Proof of Nuprl Lemma : poset-functor-extends-box-faces

Step * 2 1 3 of Lemma poset-functor-extends-box-faces

1. G : Groupoid
2. I : Cname List
3. J : nameset(I) List
4. x : nameset(I)
5. i : ℕ2
6. bx : open_box(cubical-nerve(cat(G));I;J;x;i)
7. ¬↑null(J)
8. (∃j1∈J. (∃j2∈J. ¬(j1 = j2 ∈ Cname)))
9. i1 : ℕ||bx||
10. ∀f:name-morph(I-[dimension(bx[i1])];[]). (((dimension(bx[i1]):=direction(bx[i1])) o f) ∈ name-morph(I;[]))
11. i2 : nameset(I-[dimension(bx[i1])])
12. c : {c:name-morph(I-[dimension(bx[i1])];[])| (c i2) = 0 ∈ ℕ2}
13. ((dimension(bx[i1]):=direction(bx[i1])) o c) ∈ name-morph(I;[])
14. (((dimension(bx[i1]):=direction(bx[i1])) o c) i2) = 0 ∈ ℕ2

15. (cube(bx[i1]) ((dimension(bx[i1]):=direction(bx[i1])) o c) flip(((dimension(bx[i1]):=direction(bx[i1])) o c);i2)

     (λx.Ax))
= nerve_box_edge(bx;((dimension(bx[i1]):=direction(bx[i1])) o c);i2)
∈ (cat-arrow(cat(G)) nerve_box_label(bx;((dimension(bx[i1]):=direction(bx[i1])) o c))
   nerve_box_label(bx;flip(((dimension(bx[i1]):=direction(bx[i1])) o c);i2)))
⊢ (cube(bx[i1]) c flip(c;i2) (λx.Ax))
= nerve_box_edge(bx;((dimension(bx[i1]):=direction(bx[i1])) o c);i2)
∈ (cat-arrow(cat(G)) nerve_box_label(bx;((dimension(bx[i1]):=direction(bx[i1])) o c))
   nerve_box_label(bx;((dimension(bx[i1]):=direction(bx[i1])) o flip(c;i2))))
BY
{ (NthHypEq (-1) THEN EqCD THEN Try (TrueCD) THEN Try (Fold `member` 0)) }

1
.....subterm..... T:t
1:n
1. G : Groupoid
2. I : Cname List
3. J : nameset(I) List
4. x : nameset(I)
5. i : ℕ2
6. bx : open_box(cubical-nerve(cat(G));I;J;x;i)
7. ¬↑null(J)
8. (∃j1∈J. (∃j2∈J. ¬(j1 = j2 ∈ Cname)))
9. i1 : ℕ||bx||
10. ∀f:name-morph(I-[dimension(bx[i1])];[]). (((dimension(bx[i1]):=direction(bx[i1])) o f) ∈ name-morph(I;[]))
11. i2 : nameset(I-[dimension(bx[i1])])
12. c : {c:name-morph(I-[dimension(bx[i1])];[])| (c i2) = 0 ∈ ℕ2}
13. ((dimension(bx[i1]):=direction(bx[i1])) o c) ∈ name-morph(I;[])
14. (((dimension(bx[i1]):=direction(bx[i1])) o c) i2) = 0 ∈ ℕ2

15. (cube(bx[i1]) ((dimension(bx[i1]):=direction(bx[i1])) o c) flip(((dimension(bx[i1]):=direction(bx[i1])) o c);i2)

     (λx.Ax))
= nerve_box_edge(bx;((dimension(bx[i1]):=direction(bx[i1])) o c);i2)
∈ (cat-arrow(cat(G)) nerve_box_label(bx;((dimension(bx[i1]):=direction(bx[i1])) o c))
   nerve_box_label(bx;flip(((dimension(bx[i1]):=direction(bx[i1])) o c);i2)))
⊢ (cat-arrow(cat(G)) nerve_box_label(bx;((dimension(bx[i1]):=direction(bx[i1])) o c))
   nerve_box_label(bx;((dimension(bx[i1]):=direction(bx[i1])) o flip(c;i2))))
= (cat-arrow(cat(G)) nerve_box_label(bx;((dimension(bx[i1]):=direction(bx[i1])) o c))
   nerve_box_label(bx;flip(((dimension(bx[i1]):=direction(bx[i1])) o c);i2)))
∈ Type

2
.....subterm..... T:t
2:n
1. G : Groupoid
2. I : Cname List
3. J : nameset(I) List
4. x : nameset(I)
5. i : ℕ2
6. bx : open_box(cubical-nerve(cat(G));I;J;x;i)
7. ¬↑null(J)
8. (∃j1∈J. (∃j2∈J. ¬(j1 = j2 ∈ Cname)))
9. i1 : ℕ||bx||
10. ∀f:name-morph(I-[dimension(bx[i1])];[]). (((dimension(bx[i1]):=direction(bx[i1])) o f) ∈ name-morph(I;[]))
11. i2 : nameset(I-[dimension(bx[i1])])
12. c : {c:name-morph(I-[dimension(bx[i1])];[])| (c i2) = 0 ∈ ℕ2}
13. ((dimension(bx[i1]):=direction(bx[i1])) o c) ∈ name-morph(I;[])
14. (((dimension(bx[i1]):=direction(bx[i1])) o c) i2) = 0 ∈ ℕ2

15. (cube(bx[i1]) ((dimension(bx[i1]):=direction(bx[i1])) o c) flip(((dimension(bx[i1]):=direction(bx[i1])) o c);i2)

= (cube(bx[i1]) ((dimension(bx[i1]):=direction(bx[i1])) o c) flip(((dimension(bx[i1]):=direction(bx[i1])) o c);i2)

(λx.Ax))
∈ (cat-arrow(cat(G)) nerve_box_label(bx;((dimension(bx[i1]):=direction(bx[i1])) o c))
nerve_box_label(bx;((dimension(bx[i1]):=direction(bx[i1])) o flip(c;i2))))

3
1. G : Groupoid
2. I : Cname List
3. J : nameset(I) List
4. x : nameset(I)
5. i : ℕ2
6. bx : open_box(cubical-nerve(cat(G));I;J;x;i)
7. ¬↑null(J)
8. (∃j1∈J. (∃j2∈J. ¬(j1 = j2 ∈ Cname)))
9. i1 : ℕ||bx||
10. ∀f:name-morph(I-[dimension(bx[i1])];[]). (((dimension(bx[i1]):=direction(bx[i1])) o f) ∈ name-morph(I;[]))
11. i2 : nameset(I-[dimension(bx[i1])])
12. c : {c:name-morph(I-[dimension(bx[i1])];[])| (c i2) = 0 ∈ ℕ2}
13. ((dimension(bx[i1]):=direction(bx[i1])) o c) ∈ name-morph(I;[])
14. (((dimension(bx[i1]):=direction(bx[i1])) o c) i2) = 0 ∈ ℕ2

15. (cube(bx[i1]) ((dimension(bx[i1]):=direction(bx[i1])) o c) flip(((dimension(bx[i1]):=direction(bx[i1])) o c);i2)

Latex:

Latex:
1. G : Groupoid 2. I : Cname List 3. J : nameset(I) List 4. x : nameset(I) 5. i : \mBbbN{}2 6. bx : open\_box(cubical-nerve(cat(G));I;J;x;i) 7. \mneg{}\muparrow{}null(J) 8. (\mexists{}j1\mmember{}J. (\mexists{}j2\mmember{}J. \mneg{}(j1 = j2))) 9. i1 : \mBbbN{}||bx|| 10. \mforall{}f:name-morph(I-[dimension(bx[i1])];[]) (((dimension(bx[i1]):=direction(bx[i1])) o f) \mmember{} name-morph(I;[])) 11. i2 : nameset(I-[dimension(bx[i1])]) 12. c : \{c:name-morph(I-[dimension(bx[i1])];[])| (c i2) = 0\} 13. ((dimension(bx[i1]):=direction(bx[i1])) o c) \mmember{} name-morph(I;[]) 14. (((dimension(bx[i1]):=direction(bx[i1])) o c) i2) = 0 15. (cube(bx[i1]) ((dimension(bx[i1]):=direction(bx[i1])) o c) flip(((dimension(bx[i1]):=direction(bx[i1])) o c);i2) (\mlambda{}x.Ax)) = nerve\_box\_edge(bx;((dimension(bx[i1]):=direction(bx[i1])) o c);i2) \mvdash{} (cube(bx[i1]) c flip(c;i2) (\mlambda{}x.Ax)) = nerve\_box\_edge(bx;((dimension(bx[i1]):=direction(bx[i1])) o c);i2) By Latex: (NthHypEq (-1) THEN EqCD THEN Try (TrueCD) THEN Try (Fold `member` 0)) Home Index